IWSSC 2008 Tutorial Satellite Networks I: constellations · Lockheed Martin. currently being...
Transcript of IWSSC 2008 Tutorial Satellite Networks I: constellations · Lockheed Martin. currently being...
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Lloyd Wood, Cisco Systems
IWSSC 2008 Tutorial
Satellite Networks I: constellationsorbital types, uses and advantages
International Workshop on Satellite and Space Communications 2008, IWSSC 2008,1 October 2008, Toulouse, France savi.sf.net
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Who am I? What’s my perspective?
• Did masters project on satellite constellations with intersatellite links, at ENST Toulouse.
• Did PhD on same at University of Surrey.
• Went to program router code for Cisco Systems.
• Later moved into their new space team.
• Tested Cisco mobile Internet router in space on UK-DMC satellite, working with Surrey Satellite Technology Ltd and NASA Glenn.– My team was first to test IPv6 in space…
– and first to use the ‘bundle protocol’ in space.
• I’m networking-oriented. Not a channel guy!
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One reason my PhD took so long…
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• Kepler’s first law Earth mass M at focus of an ellipse. Circular orbit is just a ‘special case’ of the ellipse, where the two focii are positioned together to form one.
• Kepler’s second lawequal areas covered in equal times.
• Kepler’s third lawcircular orbits (T2œr3) are the most useful for us.
All orbits are ellipses
fast nearperigee
slow nearapogee
M
Images from other organisations are used with attribution and thanks
Wikipedia
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NORAD# orbital elements (inc, RAAN, e, arg. p., mean an.) mean motion revs. info
How to describe an orbit?
Two-line element (TLE) format designed by NORAD, introduced November 1972.
1 NNNNNC NNNNNAAA NNNNN.NNNNNNNN +.NNNNNNNN +NNNNN-N +NNNNN-N N NNNNN
2 NNNNN NNN.NNNN NNN.NNNN NNNNNNN NNN.NNNN NNN.NNNN NN.NNNNNNNNNNNNNN
year of launch,before ID in year.
year of epoch. TWO-DIGIT. NOT Y2K COMPLIANT!But claimed good until… 2056.
NORAD# Int. Desig. epoch of TLE 1st/2nd mean motion deriv. drag orbital model to use
weak one-digitline checksums.
INTELSAT 506 1 14077U 83047A 97126.05123843 -.00000246 00000-0 10000-3 0 7212 14077 5.1140 60.2055 0003526 327.1604 183.6670 1.00269306 18589
Sample FORTRAN code can be found.
126th day
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Most useful for communications –geostationary Earth orbit (GEO)
• Altitude (35786km) chosen so that satellite moves at same angular velocity as Earth’s rotation, so appears still. (period: 1 sidereal day.)
• Three satellites spaced equally around the Equator can see most of the Earth –but not the poles. (Arthur C. Clarke, 1945)
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Most useful for communications –geostationary Earth orbit (GEO)
• Altitude (35786km) chosen so that satellite moves at same angular velocity as Earth’s rotation, so appears still. (period: 1 sidereal day.)
• Three satellites spaced equally around the Equator can see most of Earth – but not the poles. (Arthur C. Clarke, 1945)
• Inmarsat’s I-4 BGAN is nearest match to this. Third sat launched 18 Aug 2008.
BBC
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Intersatellite links are an old idea…
Fig 3 from Extra-Terrestrial Relays, Arthur C. Clarke, Wireless World, 1945.
…but interconnecting geostationary satellites is still cutting-edge stuff.
commonly written as ISLs
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Satellite antennas tailor footprints
• Satellites don’t always support perfectly spherical coverage areas.
• Shaped spotbeams let you concentrate coverage and power where you want it.
• Movable antennas let you provide more support (traffic) to a region on demand.
SatMex-5
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Actual geostationary orbit use (2001)
Note gap over the Pacific – too large to span (unlike Atlantic); small populations.
Solar panels aren’t wings…
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Quick overview of Earth orbits
• Polar view compares altitudes as if all orbits lie on Equator.
• Van Allen belts and radiation environment simplified –solar wind pushes them out of circular.
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Inclined geosynchronous orbit
• Geostationary satellite reaches end of its planned life – stationkeeping fuel has run out, satellite moves in the sky south/north of the Equator. Can be used give a few hours’ connectivity cheaply each day for polar research stations.
• Forms a figure-of-eight groundtrack throughout the day. Investigated for use for mid-latitude Japan to give high-bandwidth comms with smaller footprints.
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Tundra
Useful highly elliptical orbits (HEO)
Yellow circular GEO orbit shown for scale
• Molnya (0.5sd ~12hr) and Tundra (~24hr 1sd orbits) – cover high latitudes at apogee.
• Invented by Soviet military; then Russian satellite television in 1960s. 63.4ºinclination.
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Molnya
• Molnya (0.5sd ~12hr) and Tundra (~24hr 1sd orbits) – cover high latitudes at apogee.
• Invented by Soviet military; then Russian satellite television in 1960s. 63.4ºinclination.
Useful highly elliptical orbits (HEO)
Yellow circular GEO orbit shown for scale
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Sirius Radio
Useful highly elliptical orbits (HEO)
Yellow circular GEO orbit shown for scale
• Sirius Radio adopted this model over the continental US, before merging with XM Radio, which had two geostationary satellites.
• Molnya (0.5sd ~12hr) and Tundra (~24hr 1sd orbits) – cover high latitudes at apogee.
• Invented by Soviet military; then Russian satellite television in 1960s. 63.4ºinclination.
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Optimal elliptical constellation
• Huge 2sd ~48-hr orbits with repeating groundtracks.
• Four satellites provide visibility to the entire Earth (Draim, 1987).
• Earth always inside a tetrahedron.
• Assumes Earth is flat –satellites often very low above horizon, easily obscured. Not built.
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Optimal elliptical constellation
• Huge 2sd ~48-hr orbits with repeating groundtracks.
• Four satellites provide visibility to the entire Earth (Draim, 1987).
• Earth always inside a tetrahedron.
• Assumes Earth is flat –satellites often very low above horizon, easily obscured. Not built.
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Optimal elliptical constellation
• Huge 2sd ~48-hr orbits with repeating groundtracks.
• Four satellites provide visibility to the entire Earth (Draim, 1987).
• Earth always inside a tetrahedron.
• Assumes Earth is flat –satellites often very low above horizon, easily obscured. Not built.
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Ellipso – John E. Draim again• Use of elliptical apogee to
provide service at the northern high polar regions.
• Circular MEO orbit covers equatorial areas.
• Coverage of south poor: ‘my business plan can do without the people on Easter Island.’– David Castiel, Wired 1.05
• Business plan to sell voice telephony. Oops. Not built. Merged into ICO.
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Shadowing and urban canyons
• No. of satellites you can see above horizon is diversity.
Galileo – lots of satellites in view.
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Shadowing and urban canyons
• No. of satellites you can see above horizon is diversity.
• But buildings/trees block your view of the horizon, limiting the number of satellites you can see.
• Skyscrapers and urban canyons mean no view of the sky (why Sirius Radioand XM Radio build city repeaters).
Galileo – lots of satellites in view.…if you’re not standing in a city street.
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Navigation constellations
• Galileo and GPS(and Glonass) need to have high satellite diversity.
• You really need to see at least four satellites for a quick and accurate positioning fix (including height).
Galileo
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Communication system capacity
• Multiple spotbeams let you reuse precious frequencies multiple times, increasing use.
• Reuse of frequencies by different spotbeams over multiple satellites increases overall system capacity.
ICO satellite footprint approximation
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Communication system capacity
• Multiple spotbeams let you reuse precious frequencies multiple times, increasing use.
• Reuse of frequencies by different spotbeams over multiple satellites increases overall system capacity.
ICO satellite footprint approximation7-colour frequency reuse
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Spotbeams!
huge fold-out9m deployable
reflector
transmitters/receivers
Qinetiq
Inmarsat-4 satelliteBroadband Global Area Network (BGAN)
first launched November 2005
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ThurayaSatphone service
launched October 2000
12m reflector
Boeing
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Uplink and downlink choices
traditional ‘bent-pipe’switching on groundcan lead to ‘double hops’
newer ‘onboard processing’gaining some acceptance
with different tradeoffs.
frequency-shift (down slightly)
and amplify
decode to baseband and
clean up signal
Can make a choice –where to go down? Another spotbeam?Intersatellite link?
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Globalstar vs Iridium
bent-pipeCDMA recombination.
Uses diversity, but must complete link in nearby ground station
across intersatellite links to satellitethat sees ground station
onboard processingDoesn’t use CDMA or diversity.
But doesn’t need a nearby ground station; less ground infrastructure.
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Globalstar coverage
where its satellites can connect you to a local ground stationnotice Cuba – interdicted.
Globalstar Inc.
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satellitecoverage
areas
street ofcoverage
motionrelative to
ground
orbital seam (coverage overlaps even more)
ascending satellites (moving towards north pole)
descending satellites (moving away from north pole)
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Walker star constellations• Walker star geometry, based
on Adams/Rider ‘streets of coverage’. Best diversity at poles, worst at Equator.
• Has orbital seam where ascending and descending planes pass each other and must overlap.
• Circular orbits are most useful throughout the orbital period – signal strength remains consistent.
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orbital seam (coverage overlaps even more)
ascending satellites (moving towards north pole)
descending satellites (moving away from north pole)
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Walker star constellations• Walker star geometry, based
on Adams/Rider ‘streets of coverage’. Best diversity at poles, worst at Equator.
• Has orbital seam where ascending and descending planes pass each other and must overlap.
• Only operating example: Iridium (Voice telephony. Went through bankruptcy protection 1999-2001.)
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orbital seam
Walker star constellations• Walker star geometry, based
on Adams/Rider ‘streets of coverage’. Best diversity at poles, worst at Equator.
• Has orbital seam where ascending and descending planes pass each other and must overlap.
• Only operating example: Iridium (Voice telephony. Went through bankruptcy protection 1999-2001.)
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N
no orbital seam;ascending and descending satellites overlap
Ballard rosette (also Walker delta)
• Best diversity at mid-latitudes.
• Usually no coverage at poles; not global.
• Only operating LEO example: Globalstar(Voice telephony. Also went through US bankruptcy protection after Iridium did, 2002-2004.)
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Ballard rosette (also Walker delta)
• Best diversity at mid-latitudes.
• Usually no coverage at poles; not global.
• Only operating LEO example: Globalstar(Voice telephony. Also went through US bankruptcy protection after Iridium did, 2002-2004.)
ascending and descending satellites overlap
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A star is a rosette cut in half
1 2
ascending satellites
descending satellites
constellations offsetslightly for clarity
orbital seam
11 2
ascending satellites
descending satellites
constellations offsetslightly for clarity
orbital seam
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Topologically speaking, a rosette is a torus mapped onto a sphere;a Walker star is half a torus stitched onto a sphere.
A star has one surface of satellites over the Earth, a rosette, two.
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Globalstar Inc. vs Iridium Satellite
Both are planning replacement constellations as existing satellites near end of life.
>20% of Iridium Satellite’s profits is from polar regions.Globalstar Inc. spent $1.1 million buying Brazilian gateway operator.
Compare Q2 2008 results for three months ending 30 June.
$26 million($2 million) lossEBITDA
Iridium NEXT downselected to: Thales Alenia Space, Lockheed Martin.
currently being integrated and tested by Thales Alenia Space.
new satellites
$82 million$16.7 millionrevenue
280,000316,000subscribers
Iridium SatelliteGlobalstar Inc.
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• 1994: 840 satellites –announced the largest network system ever.
The incredible shrinking Teledesic
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• 1994: 840 satellites –announced the largest network system ever.
• Until 1997: planned 288 satellites. Still biggest!
The incredible shrinking Teledesic
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• 1994: 840 satellites –announced the largest network system ever.
• Until 1997: planned 288 satellites. Still biggest!
• Also most intersatellite links; redundant mesh even crossing the seam.
The incredible shrinking Teledesic
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ICO bankruptcy protection: 1999-2000
• 1994: 840 satellites –announced the largest network system ever.
• Until 1997: planned 288 satellites. Still biggest!
• Also most intersatellite links; redundant mesh even crossing the seam.
The incredible shrinking Teledesic
• Until 2002, down to thirty MEO satellites…
• Then bought ICO Global(which planned ten MEO sats for telephony; no ISLs and only one in orbit.)
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New kid on the block: Google.Needs satellite imagery for Google Maps and Google Earth. Gets ~4m resolution imagery from GeoEye-1 (launched 6 Sep 2008).
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Continuous coverage only needed for continuous communication
• Orbcomm is a ‘little LEO’constellation for simple messaging. Satellites are just simple VHF repeaters. Message delivered to ground station when satellite is in view.
• Store and forward – but here it’s at the sender, not on the satellite.
• …and US bankruptcy protection 2000-2001.
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Some views of intersatellite links
• Iridium has 10Mbps Ka-band radio crosslinks.
• ESA plans backhauling LEO remote sensing satellites. Demonstrated with SILEX laserlong-distance crosslink and Artemis Ka-band.
• US DoD wants reachback to CONUS from theatre. Building TSAT Transformational Satellites – five geostationary satellites with long-distance laser crosslinks.
• Clustering and slot clouds short-distance wireless connecting stationkeeping satellites.
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LEO remote sensing satellites
• LEO sun-synchronous orbits (inclination varies with altitude) are very useful; satellite ascends over the Equator at the same time every day everywhere on Earth. Makes it easier to calibrate, correct and compare your images, e.g Landsat and the growing commercial imaging market.
• Also GEO imaging satellites for wide-area weather patterns, e.g. Meteosat.
• Triana – Al Gore proposed imaging from Earth-Sun Lagrange L1 point.
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CommsImaging
Disaster Monitoring Constellation
• Single plane of four active sun-synchronous imaging satellites, ascending at 10:15am over Equator. Fifth satellite at 10:30am.
• Gives overlapping daily coverage of any point on the Earth’s surface.
• Coverage map shows 600km pushbroom imaging swath – large by LEO imaging standards. More to be launched
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Comms
Disaster Monitoring Constellation
• Single plane of four active sun-synchronous imaging satellites, ascending at 10:15am over Equator. Fifth satellite at 10:30am.
• Gives overlapping dailycoverage of any point on the Earth’s surface.
• Communications access a little larger – passes over ground stations
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Sample Disaster Monitoring Constellation (DMC) image
The Cape of Good Hope and False Bay. False colours – red is vegetation. Taken by UK-DMC satellite on the morning of Wednesday, 27 August 2008.
First sensor imagery delivered by bundles from space.
www.dmcii.com
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Other sensing satellites• Radar imaging satellites are
active, not passive sensors.
• They don’t have the daytime restrictions of imaging satellites – but night is still a strain on batteries.
• So these can be sun-synchronous at dawn and dusk – riding the day/night terminator, solar cells always in sunlight.
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Sensing benefits from ISLs• backhauling through GEO to give longer
periods of connectivity to download data, e.g. half an hour instead of ten minutes.
• Synchronising payloads on different sensor satellites, so that measurements taken at the same time can be combined.– 3D stereoscopic imaging
– Wide-aperture phased-array sensing
– combined hyperspectral imaging,• e.g. combining the capabilities of the climate-sensing ‘A-train’.
– scientific measurements otherwise not possible,
• e.g. GRACE gravity measurement (launched March 2002).
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Summary
This talk has outlined:
• An overview of satellite orbits and coverage.
• A number of satellite constellation designs
• Their varied advantages, uses, and tradeoffs.
• Intersatellite links and design choices.
• Business plans using constellations – the successful and unsuccessful ones.
• A boom-and-bust cyclical industry.
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Questions?
Thankyou
Lloyd Woodhttp://info.ee.surrey.ac.uk/L.Wood/
oh, just google…
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